functional_data
Simple and non-intrusive code generator for boilerplate of data types. The package generates a simple mixin with
operator==, hashCode, copyWith, toString, as well as lenses.
Boiler plate
Because the boiler plate is generated as a mixin, it is minimally intrusive on the interface of the class. You only have to provide a constructor with named arguments for all fields and extend the generated mixin.
@FunctionalData()
class Person extends _$Person {
final String name;
final int age;
const Person({this.name, this.age});
const Person.anonymous() : this(name: "John Doe", age: null);
int get ageInDays => 356 * age;
}
Because of this design, you have complete control over the class. You can, for example, add named constructors or methods to the class like you're used to.
Using
To use functional_data, add the following dependencies to your package:
dependencies:
functional_data:
dev_dependencies:
build_runner:
functional_data_generator:
And run flutter packages pub run build_runner build lib to generate code.
Lenses
For every class, lenses are generated for all fields which allow viewing a field or creating a new
instance of the classes with that field modified in some way. For example, the lens of Person's name is
Person$.name. To focus a lens on a specific instance use its of method:
final teacher = Person(name: "Arthur", age: 53);
print(Person$.name.of(teacher).value);
// -> "Arthur"
print(Person$.age.of(teacher).update(60);
// -> Person(name: "Arthur", age: 60)
print(Person$.name.of(teacher).map((name) => name.toUpperCase()));
// -> Person(name: "ARTHUR", age: 53)
This isn't very exciting yet. The power of lenses comes to light when you combine them. It allows you to easily
create a copy of a large nested data structure with one of the fields in a leaf modified. Two lenses can be chained
using then.
class Course extends _$Course {
final String name;
final List<Person> students;
const Course({this.students});
}
final programming = Course(name: "Programming 101", students: [Person(name: "Jane", age: 21), Person(name: "Tom", age: 20)]);
final firstStudentsName = Course$.students.then(List$.first<Person>()).then(Person$.name);
print(firstStudentsName.of(programming).update("Marcy"));
// -> Course(students: [Person(name: "Marcy", age: 21), Person(name: "Tom", age: 20)]
Compare this with the alternative:
final firstStudent = programming.students.first;
final updatedFirstStudent = Person(name: "Marcy", age: firstStudent.age);
final updatedStudents = [updatedFirstStudent] + programming.students.skip(1);
final updatedCourse = Course(name: programming.name, students: updatedStudents);
This is much less readable and error prone. Imagine what happens when one of the classes gains a field.
Class level configuration
To specify which features should be generated for the class, you can send arguments to @FunctionalData generator.
Example:
@FunctionalData(
generateCopy: false,
generateLenses: false,
)
class Foo extends _$Foo {}
Project level configuration
To specify which features should be generated for you whole project, create a file called functional_data_options.yaml
in the root of your project.
Class specific arguments will override the project level configuration.
Example with all possible configurations:
generateCopyWith: false
generateCopyUsing: false
generateLenses: false
Full example:
// lens.dart
import 'package:collection/collection.dart';
import 'package:functional_data/functional_data.dart';
part 'lens.g.dart';
// Only requirement is that it has a constructor with named arguments for all fields
@FunctionalData()
class Foo extends _$Foo {
final int number;
final String name;
const Foo({this.number, this.name});
}
@FunctionalData()
class Bar extends _$Bar {
final Foo foo;
@CustomEquality(DeepCollectionEquality())
final List<Foo> foos;
final String driver;
const Bar({this.foo, this.foos, this.driver});
}
void main() {
final foo = Foo(number: 42, name: "Marvin");
final bar = Bar(foo: foo, foos: [Foo(number: 101, name: "One"), Foo(number: 102, name: "Two")], driver: "One");
final fooName = Bar$.foo.then(Foo$.name);
// print(fooName.map((name) => name.toUpperCase(), bar));
print(fooName.of(bar).map((name) => name.toUpperCase()));
// Bar(foo: Foo(number: 42, name: MARVIN), foos: [Foo(number: 101, name: One), Foo(number: 102, name: Two)], driver: One)
final firstFooName = Bar$.foos.then(List$.atIndex<Foo>(0)).then(Foo$.name);
// print(firstFooName.update(bar, "Twee"));
print(firstFooName.of(bar).update("Twee"));
// Bar(foo: Foo(number: 42, name: Marvin), foos: [Foo(number: 101, name: Twee), Foo(number: 102, name: Two)], driver: One)
final nameOfFooNamedTwo = Bar$.foos.then(List$.where<Foo>((foo) => foo.name == "Two")).then(Foo$.name);
print(nameOfFooNamedTwo.update(bar, "Due"));
// Bar(foo: Foo(number: 42, name: Marvin), foos: [Foo(number: 101, name: One), Foo(number: 102, name: Due)], driver: One)
final driversNumber =
Bar$.foos.thenWithContext((bar) => List$.where<Foo>((foo) => foo.name == bar.driver).then(Foo$.number));
print(driversNumber.of(bar).value);
// 101
}